Effect of a 60 Hz magnetic field on the behavior of Paramecium

Paramecium multimicronucleatum was used as a model cell to study the effects of 60 Hz magnetic fields on swimming behavior. When exposed to a vertical field of 0.6 T, the cells accumulated at the upper end of the cuvette. An analysis of the swimming behavior revealed that the exposure to the field increased the number of cells swimming upwards maximally at 1 min after onset of the exposure. This effect of the magnetic field was transient, disappearing within a few minutes during the exposure. It is suggested that the magnetic field may amplify to a large extent the negative gravitaxis of Paramecium. Effects of an induced electric field on the swimming behavior are also discussed.     

Assessing the ecological relevance of swimming performance traits: a case study of bluegill sunfish (<Emphasis Type="Italic">Lepomis macrochirus</Emphasis>)

A variety of fish species show habitat-related variation in traits associated with swimming performance and foraging behavior. This commonly manifests as a distinction between open water and shallow water littoral ecotypes. In bluegill sunfish (Lepomis macrochirus), open water fish exhibit greater energy economy and speed during sustained locomotion than those from the littoral, whereas littoral fish were more maneuverable than their open water counterparts. These distinctions are associated with variation in diet and foraging behavior and may represent a resource polyphenism that enhances fitness through more effective exploitation of particular habitat types. A lack of field data means that polyphenisms have not been placed in context with swimming behavior in the field. We have used 3D videography to quantify bluegill field swimming performance in open water and littoral habitats. This revealed patterns of performance variation that parallel the trait variation previously established in the laboratory. Open water fish utilized faster average swimming speeds than inshore fish, while indicators of nonlinearity and unsteadiness were greater in the littoral fish. There are, however, differences in propulsive behavior between the field and laboratory. Pectoral-fin-powered, median-paired fin swimming is rarely employed by open water fish. Field body-caudal fin swimming involves short sequences of propulsive tail beats interspersed with gliding, rather than the repeated propulsive cycles employed under steady-state conditions. This suggests a need to re-evaluate the applicability of steady-state performance traits to behavior and fitness in the field and highlights the general importance of obtaining field performance data.     

Development of locomotor behavior in wild type and spastic (sp/sp) axolotls, Ambystoma mexicanum.

The homozygous recessive spastic mutant found in the Mexican axolotl shows violent coiling and thrashing behavior when subjected to strong tactile or electrical stimulation. In order to establish the time of onset of the first behavioral manifestation of the spastic gene, an etiological analysis of the ontogeny of swimming behavior in mutants and wild type siblings was undertaken. The locomotor patterns shown by embryos in response to an electrical stimulus were analyzed quantitatively from the embryonic early flexure stage through the larval early feeding stage. Spastic larvae failed to show dorsal-up swimming frequencies equal to those of sibling controls from day 12 (Harrison stage 40) of development indicating a lack of equilibrium. Both spastics and their siblings showed "sinusoid swimming" and "coiling" behavior in response to an aversive stimulus through day 18 (Harrison state 46, early feeding stage) of development. From day 18, wild type siblings abruptly decreased "coiling" behavior and showed strong "escape swimming" in response to an intense stimulus. Spastics never developed "escape swimming" patterns but retained a mixture of "sinusoid swimming" and "coiling" patterns characteristic of pre-feeding stage larvae.     

Qualitative and quantitative behavioral traits in a community of furcocercariae trematodes: tools for species separation?

Many trematode cercariae show distinct behavioral features, which have commonly been used in species identification in combination with morphological characteristics. However, information regarding cercariae behavior has often not been quantified in detail, or it is scattered in the literature, which is why the appropriate level of precision in behavioral identity, particularly in groups of cercariae species showing considerable morphological overlap, has not been properly established. In this study, we investigated one such group, the furcocercariae trematodes, by studying their behavior in a community consisting of 8 species (Diplostomum pseudospathaceum, Ichthyocotylurus variegatus, Cotylurus brevis, Cercaria spinulosa, Australapatemom sp., Australapatemom burti, Sanguinicola sp., and Bilharziella polonica) in central Finland. Our aim was not to develop an identification formula on the basis of behavior but to investigate and propose characteristic measurements applicable in separation of cercariae species. We used a 2-level approach, first recording qualitative behavioral traits of the cercariae, including swimming type and resting position; and, second, more detailed quantitative behavioral characteristics, such as resting time, swimming time, and swimming speed. Essentially, species showing a 2-phase behavior were distinguishable according to qualitative traits (resting position), whereas with those showing continuous swimming behavior, a combination of qualitative and quantitative traits (swimming speed) was required. These results suggest that characteristics of cercariae behavior can not only be used in species identification but also in general life history comparisons investigating details of the cercariae transmission.     

Three-Dimensional Analysis of the Swimming Behavior of Daphnia magna Exposed to Nanosized Titanium Dioxide

Due to their surface characteristics, nanosized titanium dioxide particles (nTiO₂) tend to adhere to biological surfaces and we thus hypothesize that they may alter the swimming performance and behavior of motile aquatic organisms. However, no suitable approaches to address these impairments in swimming behavior as a result of nanoparticle exposure are available. Water fleas Daphnia magna exposed to 5 and 20 mg/L nTiO₂ (61 nm; polydispersity index: 0.157 in 17.46 mg/L stock suspension) for 96 h showed a significantly (p<0.05) reduced growth rate compared to a 1-mg/L treatment and the control. Using three-dimensional video observations of swimming trajectories, we observed a treatment-dependent swarming of D. magna in the center of the test vessels during the initial phase of the exposure period. Ensemble mean swimming velocities increased with increasing body length of D. magna, but were significantly reduced in comparison to the control in all treatments after 96 h of exposure. Spectral analysis of swimming velocities revealed that high-frequency variance, which we consider as a measure of swimming activity, was significantly reduced in the 5- and 20-mg/L treatments. The results highlight the potential of detailed swimming analysis of D. magna for the evaluation of sub-lethal mechanical stress mechanisms resulting from biological surface coating and thus for evaluating the effects of nanoparticles in the aquatic environment.     

被动游泳运动对小鼠抑郁样行为及其肠道菌群组成的影响

被动游泳运动可诱发小鼠抑郁样行为,游泳环境的改变已成为抑郁样行为严重程度影响因素之一。观察不同水质、水温及持续时间对被动游泳小鼠抑郁样行为的影响,并初步探讨肠道菌群组成与抑郁样行为的关系。通过不同条件下的被动游泳运动建立抑郁样行为小鼠模型。采用糖水偏好实验及强迫游泳实验评价其行为学变化;采用16S rDNA高通量测序技术及实时荧光定量PCR技术对小鼠肠道菌群进行分子生态学分析。被动游泳16周后,各模型组小鼠体质量及糖水偏爱度均较正常对照组降低,而不动时间则有所延长。其中,室温海水游泳15 min小鼠体质量及糖水偏爱度降低程度最大,不动时间最长,与正常对照组比较,均具有显著性差异（P<0.05）。各模型组小鼠肠道菌群Chao指数、Shannon指数及PCoA分析均较正常对照组具有显著性差异（P<0.05）,其从门水平到属水平的丰度也发生不同程度改变。其中,室温海水游泳15 min小鼠肠道菌群组成变化程度最大,并发生拟杆菌属、普氏菌属等多个菌属的富集以及乳杆菌属丰度的减少,实时荧光定量PCR实验也得到了较为一致的结果（P<0.05）。以上结果表明,被动游泳运动可导致小鼠抑郁样行为的发生,其肠道菌群组成也发生明显改变;同时,菌群组成的改变会随着抑郁样行为的严重程度而有所变化。     

Triglyceride lipase activity and fatty acid transport in physical endurance in rats adapted to the muscular activity

Aerobic training led to enhancement of lipase activity in type IIA type muscles. Still more obvious changes were found in rats trained to aerobic swimming with maximal intensity. In latter activity, a rise of the fatty acid-binding protein (FABP) was revealed in types I and IIA skeletal muscles. These adaptive changes led to enhancement of lipid metabolism. It was also shown that the FABP content decreased after physical exercise more obviously in the trained animals due, probably, to their substance turnover enhancement.     

Swimming behavior and ultrastructure of sperm of<Emphasis Type="Italic"> Lygodium japonicum</Emphasis> (Pteridophyta)

Swimming behavior of the sperm of Lygodium japonicum (Pteridophyta) and the associated ultrastructure of the flagellar apparatus were studied by video microscopy, transmission electron microscopy (TEM) and scanning electron microscopy (SEM). The sperm has approximately 70 flagella that emerge from a sinistrally-coiled flagellar apparatus, and swims forward by ciliary beat of these flagella. Backward swimming was not observed even after sperm collided with obstacles. Video microscopy showed that the flagella of the swimming sperm are oriented laterally and oblique-anteriorly. TEM and SEM observations revealed that the basal bodies of these flagella are arranged in at least two rows and oriented in the same directions as observed by video microscopy. These basal bodies (flagella) are categorized into two types according to their orientation: group I (laterally directed) and group II (oblique-anteriorly directed). The directionality of the basal bodies appears to be fixed by electron-dense material around their base. The outer dynein arms of the flagellar axoneme are entirely absent. These morphological characteristics of basal bodies (flagella) may relate to the lack of backward swimming behavior of the sperm. Based on these results, the evolution of swimming behavior in the archegoniates is discussed in connection with lack of backward swimming in a distantly related green alga, Mesostigma viride, and the Streptophyta.     

Behavioral effects of the aqueous extract of Guiera senegalensis in mice and rats

Behavioral effects of the aqueous extract of Guiera senegalensis on the central nervous system of mice and rats were investigated. Spontaneous motor activity, pentobarbital sleeping time, amphetamine-stereotyped behavior, exploratory activity and performance on treadmills (rota-rod) were evaluated. The results revealed that the aqueous extract of G. senegalensis reduced spontaneous motor activity in mice, prolonged the duration of pentobarbital sleeping time in rats and attenuated amphetamine-induced stereotype behavior in rats. The extract also decreased exploratory activity in mice and had no observable effects on motor coordination (rota-rod) at the doses tested. The results suggested that the crude aqueous extract of G. senegalensis possesses some biologically active principles that are sedative in nature.     

An automated assay for quantifying the swimming behavior of Paramecium and its use to study cation responses

Paramecium tetraurelia is a ciliated protist that alters its swimming behavior in response to various stimuli. Like the sensory responses of many organisms, these responses in Paramecium show adaptation to continued stimulation. For quantitative studies of the initial response to stimulation, and of the time course of adaptation, we have developed a computerized motion analysis assay that can detect deviations from the normal swimming pattern in a population of cells. The motion of an average of ten cells was quantified during periods ranging from 15 to 60 seconds, with a time resolution of 1/15 seconds. During normal forward swimming, the maximum deviation from a straight-line path was less than 17 degrees. Path deviations above this threshold value were defined as changes in swimming direction. The percentage of total path time that cells spent deviating from forward swimming was defined as percent directional changes (PDC). This parameter was used to construct dose-response curves for the behavioral effects of various externally added cations known to induce behavioral changes and also to show the time course of adaptation to a depolarizing K+ stimulus. This assay is a valuable tool for studies of chemoeffectors or mutations that alter the swimming behavior of Paramecium and may also be applicable to other motile organisms.     

The parachute function of the hull in eggs of Mopalia kennerleyi (Chitonida: Mopaliidae), and swimming of its larvae through ontogeny

Free‐spawning species of chitons produce eggs enclosed in a coating known as the hull. In Chitonida, several studies have shown that the hull helps to direct sperm to specific areas of the egg surface, facilitating fertilization. One study has found evidence that this structure also serves to reduce the sinking rates of the eggs. To clarify how the presence of the hull modifies sinking rates in chiton eggs, here we compare sinking speeds and densities of eggs of Mopalia kennerleyi with and without the hull. Sinking rates of eggs with the hull were approximately one‐third of those without it. This structure acts as a flotation device because it has a density very close to that of seawater, and it increases the effective diameter and therefore the drag on the negatively buoyant egg. Since there is limited knowledge about morphology and behavior of chiton larvae, we also analyzed changes during ontogeny in behavior, swimming speeds, and body shape of larvae of M. kennerleyi. Over time, the larvae decreased their upward swimming tendency and preferred to stay near the bottom, and their bodies became elongated and dorso‐ventrally compressed. These changes may be related to preparation for settlement and metamorphosis. Further studies of these subjects are required in chitons, since movement of early stages, as eggs/embryos sinking or larvae swimming in the water column, may affect their survival.     

Use of properties and regulation peculiarities of enzymes of glycogenolysis in fish skeletal muscle depending on peculiarities of motor activity of species

Levels of activity, properties, and peculiarities of activation of glycogen phosphorylase (GP; EC 2.4.1.1) and glycogen phosphorylase kinase (GPK; EC 2.7.1.38) were studied in the white skeletal muscle of fish differing in motor behavior. No differences in the GP and GPK activity levels were revealed in laskir Diplodus annularis (L.), horse mackerel Trachurus mediterraneus ponticus, salmon Salmo trutta morphario, scorpena Scorpaena porcus, Scophtalnus maeoticus, and carp Cyprinus carpio; however, properties of the isolated enzymes and peculiarities of formation of their activated forms during swimming in a hydrodynamic tube are determined by functional peculiarities of the muscle tissue and are associated with the motor activity character of the species. In fish capable for the spurt type of swimming (scorpena, salmon) the more rapid ion regulation plays the predominant role. In other species, the glycogenolysis hormonal regulation leading to a change of the GPK activity index has been found.     

Consequences of thermal acclimation for the mating behaviour and swimming performance of female mosquito fish

The mating system of eastern mosquito fish (Gambusia holbrooki) is dominated by male sexual coercion, where all matings are forced and females never appear to cooperate and actively avoid all attempts. Previous research has shown that male G. holbrooki offer a model system for examining the benefits of reversible thermal acclimation for reproductive success, but examining the benefits to female avoidance behaviour has been difficult. In this study, we examined the ability of non-male-deprived female G. holbrooki to avoid forced-coercive matings following acclimation to either 18 or 30 degrees C for six weeks (12h light:12h dark photoperiod). Thermal acclimation of burst and sustained swimming performance was also assessed, as these traits are likely to underlie their ability to avoid forced matings. There was no influence of thermal acclimation on the burst swimming performance of female G. holbrooki over the range 18-30 degrees C; however, sustained swimming performance was significantly lower in the warm- than the cool-acclimation group. For mating behaviour, we tested the hypothesis that acclimation would enhance the ability of female G. holbrooki to avoid forced matings at their host acclimation temperature relative to females acclimated to another environment. However, our hypothesis was not supported. The rate of copulations was almost three times greater for females acclimated to 30 degrees C than 18 degrees C when tested at 30 degrees C, indicating that they possess the ability to alter their avoidance behaviour to 'allow' more copulations in some environments. Coupled with previous studies, female G. holbrooki appear to have greater control on the outcome of coercive mating attempts than previously considered and can alter their propensity to receive forced matings following thermal acclimation. The significance of this change in female mating-avoidance behaviours with thermal acclimation remains to be explored.     

Ion selectivity of the Vibrio alginolyticus flagellar motor.

The marine bacterium, Vibrio alginolyticus, normally requires sodium for motility. We found that lithium will substitute for sodium. In neutral pH buffers, the membrane potential and swimming speed of glycolyzing bacteria reached maximal values as sodium or lithium concentration was increased. While the maximal potentials obtained in the two cations were comparable, the maximal swimming speed was substantially lower in lithium. Over a wide range of sodium concentration, the bacteria maintained an invariant sodium electrochemical potential as determined by membrane potential and intracellular sodium measurements. Over this range the increase of swimming speed took Michaelis-Menten form. Artificial energization of swimming motility required imposition of a voltage difference in concert with a sodium pulse. The cation selectivity and concentration dependence exhibited by the motile apparatus depended on the viscosity of the medium. In high-viscosity media, swimming speeds were relatively independent of either ion type or concentration. These facts parallel and extend observations of the swimming behavior of bacteria propelled by proton-powered flagella. In particular, they show that ion transfers limit unloaded motor speed in this bacterium and imply that the coupling between ion transfers and force generation must be fairly tight.     

Microscopic analysis of bacterial motility at high pressure

The bacterial flagellar motor is a molecular machine that converts an ion flux to the rotation of a helical flagellar filament. Counterclockwise rotation of the filaments allows them to join in a bundle and propel the cell forward. Loss of motility can be caused by environmental factors such as temperature, pH, and solvation. Hydrostatic pressure is also a physical inhibitor of bacterial motility, but the detailed mechanism of this inhibition is still unknown. Here, we developed a high-pressure microscope that enables us to acquire high-resolution microscopic images, regardless of applied pressures. We also characterized the pressure dependence of the motility of swimming Escherichia coli cells and the rotation of single flagellar motors. The fraction and speed of swimming cells decreased with increased pressure. At 80 MPa, all cells stopped swimming and simply diffused in solution. After the release of pressure, most cells immediately recovered their initial motility. Direct observation of the motility of single flagellar motors revealed that at 80 MPa, the motors generate torque that should be sufficient to join rotating filaments in a bundle. The discrepancy in the behavior of free swimming cells and individual motors could be due to the applied pressure inhibiting the formation of rotating filament bundles that can propel the cell body in an aqueous environment.     

Ecomorphology of Locomotion in Labrid Fishes

The Labridae is an ecologically diverse group of mostly reef associated marine fishes that swim primarily by oscillating their pectoral fins. To generate locomotor thrust, labrids employ the paired pectoral fins in motions that range from a fore-aft rowing stroke to a dorso-ventral flapping stroke. Species that emphasize one or the other behavior are expected to benefit from alternative fin shapes that maximize performance of their primary swimming behavior. We document the diversity of pectoral fin shape in 143 species of labrids from the Great Barrier Reef and the Caribbean. Pectoral fin aspect ratio ranged among species from 1.12 to 4.48 and showed a distribution with two peaks at about 2.0 and 3.0. Higher aspect ratio fins typically had a relatively long leading edge and were narrower distally. Body mass only explained 3% of the variation in fin aspect ratio in spite of four orders of magnitude range and an expectation that the advantages of high aspect ratio fins and flapping motion are greatest at large body sizes. Aspect ratio was correlated with the angle of attachment of the fin on the body (r = 0.65), indicating that the orientation of the pectoral girdle is rotated in high aspect ratio species to enable them to move their fin in a flapping motion. Field measures of routine swimming speed were made in 43 species from the Great Barrier Reef. Multiple regression revealed that fin aspect ratio explained 52% of the variation in size-corrected swimming speed, but the angle of attachment of the pectoral fin only explained an additional 2%. Labrid locomotor diversity appears to be related to a trade-off between efficiency of fast swimming and maneuverability in slow swimming species. Slow swimmers typically swim closer to the reef while fast swimmers dominate the water column and shallow, high-flow habitats. Planktivory was the most common trophic associate with high aspect ratio fins and fast swimming, apparently evolving six times.     

Downregulation of the RECK-tumor and metastasis suppressor gene in glioma invasiveness

Invasive behavior is the pathological hallmark of malignant gliomas, being responsible for the failure of surgery, radiation, and chemotherapy. Matrix metalloproteinases (MMPs) are essential for proper ECM remodeling and invasion. The tumor and metastasis suppressor RECK protein regulates at least three members of the MMPs family: MMP-2, MMP-9, and MT1-MMP. In order to mimic the in vivo invasion process, A172 and T98G, respectively, non-invasive and invasive human glioblastoma cell lines, were cultured onto uncoated (control) or type I collagen gel-coated surface, and maintained for up to 7 days to allow establishment of the invasive process. We show that the collagen substrate causes decreased growth rates and morphological alterations correlated with the invasive phenotype. Electronic transmission microscopy of T98G cells revealed membrane invaginations resembling podosomes, which are typically found in cells in the process of crossing tissue boundaries, since they constitute sites of ECM degradation. Real time PCR revealed higher RECK mRNA expression in A172 cells, when compared to T98G cells and, also, in samples obtained from cultures where the invasive process was fully established. Interestingly, the collagen substrate increases RECK expression in A172 cells and the same tendency is displayed by T98G cells. MMPs-2 and -9 displayed higher levels of expression and activity in T98G cells, and their activities are also upregulated by collagen. Therefore, we suggest that: (1) RECK downregulation is critical for the invasiveness process displayed by T98G cells; (2) type 1 collagen could be employed to modulate RECK expression in glioblastoma cell lines. Since a positive correlation between RECK expression and patients survival has been noted in several types of tumors, our results may contribute to elucidate the complex mechanisms of malignant gliomas invasiveness.     

Schooling Increases Risk Exposure for Fish Navigating Past Artificial Barriers

Artificial barriers have become ubiquitous features in freshwater ecosystems and they can significantly impact a region''s biodiversity. Assessing the risk faced by fish forced to navigate their way around artificial barriers is largely based on assays of individual swimming behavior. However, social interactions can significantly influence fish movement patterns and alter their risk exposure. Using an experimental flume, we assessed the effects of social interactions on the amount of time required for juvenile palmetto bass (Morone chrysops × M. saxatilis) to navigate downstream past an artificial barrier. Fish were released either individually or in groups into the flume using flow conditions that approached the limit of their expected swimming stamina. We compared fish swimming behaviors under solitary and schooling conditions and measured risk as the time individuals spent exposed to the barrier. Solitary fish generally turned with the current and moved quickly downstream past the barrier, while fish in groups swam against the current and displayed a 23-fold increase in exposure time. Solitary individuals also showed greater signs of skittish behavior than those released in groups, which was reflected by larger changes in their accelerations and turning profiles. While groups displayed fission-fusion dynamics, inter-individual positions were highly structured and remained steady over time. These spatial patterns align with theoretical positions necessary to reduce swimming exertion through either wake capturing or velocity sheltering, but diverge from any potential gains from channeling effects between adjacent neighbors. We conclude that isolated performance trials and projections based on individual behaviors can lead to erroneous predictions of risk exposure along engineered structures. Our results also suggest that risk perception and behavior may be more important than a fish''s swimming stamina in artificially modified systems.     

Seasonal analysis of Daphnia pulicaria swimming behavior

Our study documents individual swimming behavior of Daphnia pulicaria over a yearly cycle in a temperate lake. We collected D. pulicaria, a common freshwater zooplankton, from Lake Mendota on 10 dates between July 1994 and June 1995 from two depths, 2 m and 10 m. The Daphnia were rushed to the laboratory and video-taped as they swam in lake water under lake-ambient temperature and light conditions. Five-second swimming tracks of individual Daphnia were filmed and digitized using a motion analysis system. We measured average turning angle, swimming speed and sinking rate for each track. D. pulicaria swimming behavior varied over the annual cycle. We found significant differences in turning angle between depths and among months. Sinking rate and swimming speed were significantly different among months but not depths. Sinking rate and swimming speed were not significantly correlated with water temperature. Our results were contrary to Stokes' Law predictions, in that D. pulicaria had the slowest sinking speed in June, not in the winter when water temperatures were lowest and viscosity was highest. Body length was significantly correlated with all three swimming variables. We also studied swimming behavior in clonal populations of D. pulicaria in different concentrations of the alga, Chlamydomonas reinhardtii. D. pulicaria did not change swimming speed, turning angle or sinking rate over a range of food concentrations. Finally, swimming behavior in a D. pulicaria clone, tested at two temperatures in the laboratory, confirmed the results from our seasonal study; Daphnia did not sink as predicted by changes in viscosity.     

High levels of metacercarial infestation (family: Diplostomidae) do not affect host energetics and swimming performance in the Epaulette goby (Coryogalops sordidus,Gobiidae)

Parasites have deleterious effects on their hosts, often resulting in altered host behavior or increased energy expenditure. When organisms are exposed to suboptimal environments, parasite loading may increase. Microbialite pools along the warm temperate South African coastline have been hypothesized as refugia for Epaulette gobies (Coryogalops sordidus, Gobiidae) when they are outside of their previously known subtropical distribution. The aim of this study was to determine if C. sordidus individuals infected with metacercarial cysts display higher metabolic rates or different swimming behavior compared to noninfected individuals. We measured each goby's swimming performance using a critical station-holding speed (U_crit) test (n = 60) and visually scored their swimming behavior (n = 52) during these measurements. Also, we measured the metabolic rate of gobies using an intermittent flow respirometer system to determine standard metabolic rate (SMR) and maximum metabolic rate (MMR) from gobies at 21°C before and after swimming trials. Metacercarial load carried by infected gobies seemingly had no impact on the host's energetics (SMR or MMR), swimming ability (as repeated U_crit tests), or swimming behavior compared to noninfected gobies. Thus, the metacercarial intensity observed in gobies in the current study appeared to have no impact on host swimming performance or behavior. Furthermore, the swimming capacity observed for C. sordidus, in general, suggests that this goby is a poor swimmer compared to other gobiid species.